Deep Learning is a subset of machine learning that uses artificial neural networks with multiple layers (hence "deep") to model and understand complex patterns in datasets. It's particularly effective for tasks like image and speech recognition, natural language processing, and translation, and it's the technology behind many advanced AI systems.
This study introduces a Digital Twin (DT)-centered Fire Safety Management (FSM) framework for smart buildings. Harnessing technologies like AI, IoT, AR, and BIM, the framework enhances decision-making, real-time information access, and FSM efficiency. Evaluation by Facility Management professionals affirms its effectiveness, with a majority expressing confidence in its clarity, data security, and utility for fire evacuation planning and Fire Safety Equipment (FSE) maintenance.
Researchers present G-YOLOv5s-SS, a novel lightweight architecture based on YOLOv5 for efficient detection of sugarcane stem nodes. Achieving high accuracy (97.6% AP) with reduced model size, parameters, and FLOPs, this algorithm holds promise for advancing mechanized sugarcane cultivation, addressing challenges in seed cutting efficiency and offering potential applications in broader agricultural tasks.
Researchers introduce a novel multi-task learning approach for recognizing low-resolution text in logistics, addressing challenges in the rapidly growing e-commerce sector. The proposed model, incorporating a super-resolution branch and attention-based decoding, outperforms existing methods, offering substantial accuracy improvements for handling distorted, low-resolution Chinese text.
Researchers introduced a hybrid Ridge Generative Adversarial Network (RidgeGAN) model to predict road network density in small and medium-sized Indian cities under the Integrated Development of Small and Medium Towns (IDSMT) project. Integrating City Generative Adversarial Network (CityGAN) and Kernel Ridge Regression (KRR), the model successfully generated realistic urban patterns, aiding urban planners in optimizing layouts for efficient transportation infrastructure development.
Researchers introduced Swin-APT, a deep learning-based model for semantic segmentation and object detection in Intelligent Transportation Systems (ITSs). The model, incorporating a Swin-Transformer-based lightweight network and a multiscale adapter network, demonstrated superior performance in road segmentation and marking detection tasks, outperforming existing models on various datasets, including achieving a remarkable 91.2% mIoU on the BDD100K dataset.
Researchers from Nanjing University of Science and Technology present a novel scheme, Spatial Variation-Dependent Verification (SVV), utilizing convolutional neural networks and textural features for handwriting identification and verification. The scheme outperforms existing methods, achieving 95.587% accuracy, providing a robust solution for secure handwriting recognition and authentication in diverse applications, including security, forensics, banking, education, and healthcare.
Researchers employ deep neural networks and machine learning to predict facial landmarks and pain scores in cats using the Feline Grimace Scale. The study demonstrates advanced CNN models accurately predicting facial landmarks and an XGBoost model achieving high accuracy in discerning painful and non-painful cats. This breakthrough paves the way for an automated smartphone application, addressing the challenge of non-verbal pain assessment in felines and marking a significant advancement in veterinary care.
Researchers from China introduce the SZU-EmoDage dataset, a pioneering facial dataset crafted with StyleGAN, featuring Chinese individuals of diverse ages and expressions. This innovative dataset, validated for authenticity by human raters, surpasses existing ones, offering applications in cross-cultural emotion studies and advancements in facial perception technology. The study emphasizes the dataset's value in exploring cognitive processes, detecting disorders, and enhancing technologies like face recognition and animation.
This article delves into bolstering Internet of Things (IoT) security, specifically countering botnet attacks that jeopardize IoT ecosystems. Employing tree-based algorithms, including Decision Trees, Random Forest, and boosting techniques, the researchers conduct a thorough empirical analysis, highlighting Random Forest's standout multi-class classification accuracy and superior computational efficiency.
This paper introduces SCANN, an interpretable deep learning architecture with attention mechanisms tailored for comprehending material structures and predicting properties. Utilizing iterative learning and global attention scores, SCANN excels in capturing complex structure-property relationships, outperforming traditional methods. The study demonstrates SCANN's robust predictive capabilities across diverse datasets, emphasizing its interpretative capacity to unveil how material properties correlate with specific structural features, thereby guiding future advancements in material design and discovery.
This article presents a novel workflow for generating high-resolution lithology logs from conventional well logs, addressing challenges in multiclass imbalanced data classification. The enhanced weighted average ensemble approach, incorporating error-correcting output code (ECOC) and cost-sensitive learning (CSL) techniques, outperforms traditional machine learning algorithms.
Researchers proposed an IoT and ML-based approach to analyze ornamental goldfish behavior in response to environmental changes, particularly real-time water temperature and dissolved oxygen concentration. Utilizing IoT sensors and machine learning classifiers like Decision Tree, Naïve Bayes, Linear Discriminant Analysis, and K-Nearest Neighbor, the study demonstrated the effectiveness of the Decision Tree classifier in accurately classifying behavioral changes.
The article presents a groundbreaking approach for identifying sandflies, crucial vectors for various pathogens, using Wing Interferential Patterns (WIPs) and deep learning. Traditional methods are laborious, and this non-invasive technique offers efficient sandfly taxonomy, especially under field conditions. The study demonstrates exceptional accuracy in taxonomic classification at various levels, showcasing the potential of WIPs and deep learning for advancing entomological surveys in medical vector identification.
This article introduces an AI-based solution for real-time detection of safety helmets and face masks on municipal construction sites. The enhanced YOLOv5s model, leveraging ShuffleNetv2 and ECA mechanisms, demonstrates a 4.3% increase in mean Average Precision with significant resource savings. The study emphasizes the potential of AI-powered systems to improve worker safety, reduce accidents, and enhance efficiency in urban construction projects.
This research, published in PLOS One, investigates the protective feature preferences of the adult Danish population in various AI decision-making scenarios. With a focus on both public and commercial sectors, the study explores the nuanced interplay of demographic factors, societal expectations, and trust in shaping preferences for features such as AI knowledge, human responsibility, non-discrimination, human explainability, and system performance.
This research introduces FakeStack, a powerful deep learning model combining BERT embeddings, Convolutional Neural Network (CNN), and Long Short-Term Memory (LSTM) for accurate fake news detection. Trained on diverse datasets, FakeStack outperforms benchmarks and alternative models across multiple metrics, demonstrating its efficacy in combating false news impact on public opinion.
Researchers developed a cutting-edge robot welding guidance system, integrating an enhanced YOLOv5 algorithm with a RealSense Depth Camera. Overcoming limitations of traditional sensors, the system enables precise weld groove detection, enhancing welding robot autonomy in complex industrial environments. The experiment showcased superior accuracy, reaching 90.8% mean average precision, and real-time performance at 20 FPS, marking a significant stride in welding automation and precision.
A groundbreaking study introduces the IGP-UHM AI v1.0 model, utilizing deep learning and XAI to enhance El Niño-Southern Oscillation (ENSO) prediction. The 2023–2024 forecast reveals sustained yet weakening EN conditions, emphasizing the model's credibility through Layerwise Relevance Propagation (LRP) explanations. The research underscores the need for ongoing refinement, human oversight, and raises crucial questions about ENSO predictability limits in the context of climate change.
Researchers propose Med-MLLM, a Medical Multimodal Large Language Model, as an AI decision-support tool for rare diseases and new pandemics, requiring minimal labeled data. The framework integrates contrastive learning for image-text pre-training and demonstrates superior performance in COVID-19 reporting, diagnosis, and prognosis tasks, even with only 1% labeled training data.
Researchers propose an innovative fault monitoring approach for high-voltage circuit breakers, utilizing a specialized device and deep learning techniques. The unsupervised deep learning method showcases over 95% accuracy in fault diagnosis, outperforming traditional algorithms in feature extraction and computation speed. The study suggests a practical and efficient solution for real-time fault monitoring, holding promise for enhancing reliability in high-voltage systems.
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